Upload
nguyenhuong
View
218
Download
1
Embed Size (px)
Citation preview
GROUND-WATER RESOURCES OF WILLIAMSBURG COUNTY,
SOUTH CAROLINASTATE OF SOUTH CAROLINADEPARTMENT OF NATURAL
RESOURCES
LAND, WATER AND CONSERVATION DIVISION
WATER RESOURCESREPORT 49
2008
GROUND-WATER RESOURCES OF WILLIAMSBURG COUNTY,
SOUTH CAROLINA
by
Roy Newcome, Jr.
STATE OF SOUTH CAROLINADEPARTMENT OF NATURAL RESOURCES
LAND, WATER AND CONSERVATION DIVISION
WATER RESOURCES REPORT 49
2008
This document is available on the Department of Natural Resources web site: http://www.dnr.sc.gov/
STATE OF SOUTH CAROLINAThe Honorable Mark H. Sanford, Governor
South Carolina Department of Natural Resources
Board Members
Michael G. McShane, Chairman ......................................................................................................... Member-at-Large
R. Michael Campbell, II, Vice-Chairman ..............................................................................2nd Congressional District
Caroline C. Rhodes .................................................................................................................1st Congressional District
Stephen L. Davis .................................................................................................................... 3rd Congressional District
Norman F. Pulliam ..................................................................................................................4th Congressional District
Frank Murray, Jr. .....................................................................................................................5th Congressional District
John P. Evans ..........................................................................................................................6th Congressional District
John E. Frampton, Director
Land, Water and Conservation Division
Steven J. de Kozlowski, Acting Deputy Director
A.W. Badr, Ph.D., Chief, Hydrology Section
ii
CONTENTS
Page
Abstract .............................................................................................................................................................................. 1Introduction ........................................................................................................................................................................ 1 Development ................................................................................................................................................................ .1 Climate .......................................................................................................................................................................... 1 Physiography and drainage ........................................................................................................................................... 1 Water supply ................................................................................................................................................................. 1 Previous studies ............................................................................................................................................................ 5Aquifers and wells ............................................................................................................................................................. 5Locating the aquifers .......................................................................................................................................................... 5Testing the wells and aquifers ............................................................................................................................................ 8Effects of pumping ............................................................................................................................................................. 8Quality of the water ......................................................................................................................................................... 15Water Levels .................................................................................................................................................................... 15Summary and conclusions ............................................................................................................................................... 15References ........................................................................................................................................................................ 19
1-7 Maps showing:1. Location, towns, and major drainage of Williamsburg County S.C ................................................................ 22. Topographic-map coverage .............................................................................................................................. 33. Wells capable of producing 200 gallons per minute or more ........................................................................... 64. Structure contours relating to the major aquifer .............................................................................................. 75. Contours depicting the deepest extent of freshwater ....................................................................................... 76. Selected wells for which electric logs are available ......................................................................................... 97. Locations of wells for which pumping tests have been made ........................................................................ 12
8. Graphs showing predicted pumping effects at various times and distances ....................................................... 13,14
9-10 Maps showing:9. Locations of wells for which chemical analyses are available ...................................................................... 1710. Potentiometric contours for the Black Creek and Middendorf Formations ................................................... 18
TABLES
1. Wells used by the major public water supplies serving Williamsburg County, S.C. ....................................... 42. Freshwater-sand intervals on electric logs ..................................................................................................... 103. Results of pumping tests of wells................................................................................................................... 114. Chemical analyses of water from wells ......................................................................................................... 16
iii
1
GROUND-WATER RESOURCES OF WILLIAMSBURG COUNTY, SOUTH CAROLINA2008
by Roy Newcome, Jr.
ABSTRACT
Williamsburg County, S.C., has numerous substantial ground-water aquifers. Most are in sand-and-clay formations of Cretaceous Age, like the other counties of South Carolina’s Coastal Plain. Wells as deep as 1,200 feet provide water of suitable quality for public supply, industry, and agriculture. Many wells produce more than 200 gallons per minute; the largest yield recorded is 1,900 gallons per minute.
Chemical analyses of the well water indicate dissolved-solids concentrations generally less than 300 milligrams per liter. The water is usually very soft and low in iron. Cloudiness caused by aragonite suspension has been an occasional problem.
Withdrawals from wells in the Hemingway and Andrews areas have caused depressions in the potentiometric surface in those localities. This can be ameliorated by reduction in pumpage or repositioning of wells. Artificial recharge, using surface water, is a potential means of restoring the artesian water level.
INTRODUCTION
Williamsburg County occupies 934 square miles in eastern South Carolina and is the sixth-largest county. It presents a tilted-square area one county removed from the coastline (Fig. 1). The estimated 2006 population of the county was 36,105 (U.S. Census Bureau), less than 1 percent of the total State population. The largest town is Kingstree (population 4,400). Hemingway, Lane, and Greeleyville have about 500 people each.
One-third of Williamsburg County is farmland, the main crops being soybeans, cotton, and corn. The county is two-thirds timberland, with oak-gum-cypress woods the most common and shortleaf pine not far behind.
DEVELOPMENT
Approximately 60 businesses and industries are located in Williamsburg County. Transportation needs are served by the CSX Railroad, which enters the county from the city of Sumter and connects the towns of Greeleyville and Lane, then trends northward through Salters, Kingstree, and Cades. Another branch of CSX enters the county from Charleston and Jamestown and goes northward through Andrews, Nesmith, and Hemingway. U.S. Highways 378 in the north and 521 in the south are connected by U.S. 52 which passes through Kingstree. The nearest commercial airports are at North Charleston, 53 miles south of Kingstree, Florence, 30 miles north of Kingstree, and Myrtle Beach, 52 miles east of Kingstree.
CLIMATEThe average annual rainfall in Williamsburg County is
48.4 inches. August is the wettest month, with slightly more than 6 inches, and November the driest, with 2.5 inches. Snow is virtually a nonoccurrence. July is the warmest month and January the coldest. The annual average air temperature is
63.4º F (Fahrenheit), and this determines the temperature of shallow ground water. The 246-day median growing season runs from mid-March to mid-November.
PHYSIOGRAPHY AND DRAINAGE
Williamsburg is a county of riverine swamps and Caro-lina bays. A quick perusal of the topographic maps covering the county (see Fig. 2) will impress the observer; there is little dry land. Land-surface elevations range between 5 and 90 ft (feet) above sea level, but most of the county is between 25 and 75 ft. All or part of 27 USGS (U.S. Geological Sur-vey) topographic maps, at a scale of 1:24,000, are included in the coverage of Williamsburg County (Fig. 2).
The county is drained by the Santee River, which forms the southern border, and the Black River that flows south-easterly across the central part of the county and on which Kingstree, the largest town and the county seat, is located. Black Mingo Creek and its tributaries drain much of the northeast.
WATER SUPPLY
Five municipal water systems and two rural water sys-tems serve Williamsburg County. Nearly half of the coun-ty’s population is on these public water systems. All of the public supplies are obtained from wells (Table 1). The wells range in depth from less than 300 ft to nearly 1,100 ft and in yield from 140 to 1,050 gpm (gallons per minute). Wells also provide water for the parts of the population not on the major public systems. This includes numerous businesses, mobile-home parks, child-care centers, schools, and a few subdivi-sions. Last but not least are the many rural residences served by private wells.
Currently (2008) the public water systems pump an ag-gregate average of 2.7 mgd (million gallons per day).
2
Santee
River
Cla
ppS
wam
p
Kin
gstr
eeS
wam
pC
anal
B lack River
Bir
ch C
reek
Lane
Indiantown
Stuckey
Hemingway
Rhems
Henry
Nesmith
Earle
Trio
Andrews
Warsaw
Salters
Cades
Morrisville
Kingstree
Greeleyville
512
261
41
51
512
41
377
375
527
261
527
miles4 0 4 8
/52
/521
N
B e r k e l e y C o u n t y
F l o r e n c e C o u n t y
M a r i o nC o u n t y
Pee Dee River
Figure 1. Location, towns, and major drainage of Williamsburg County, S.C.
Ge o
r ge t
ow
n C
ou
nt y
Cl a
re n
don C
ou
nt y
3
OLANTA
MILL B
AY
HERBRON
CROSSROADS
LAKE C
ITY
WEST
LAKE C
ITY
EAST
PROSPECT
CROSSROADS
JOHNSONVILL
E
SNOW IS
LAND
FORESTON
WORKMAN
KINGSTREE
FOWLE
R
INDIA
NTOWN
HENRY
OUTLAND
BUTLERS
BAY
GREELEYVILL
E
SALTERS
KELLEHAN
CROSSROADS
WARSAW
RHEMS
SAINT
STEPHEN
BLAKELY
TRIO
ANDREWS
ALVIN
33°50’
33°40’
33°30’
33°20’
U.S. Geological Survey 7 1/2 - minute topographic quadrangles
Figure 2. Topographic-map coverage of Williamsburg County.
7
9°50
’
7
9°40
’
8
0°00
’
7
9°30
’miles0 4 8 12
4
ll2
610
kk
XX
WIL
193
13S
j22/
1991
Syst
emW
ell n
alo
catm
e or
ion
Ow
neno
.r D
epth
(fe
et)
Form
atio
nYi
eld
(gpm
)El
ectr
iclo
gC
hem
ical
anal
ysis
Pum
pin
test
g C
ount
y nu
mbe
rS.
C. g
rid
num
ber
Dat
edr
illed
Gre
eley
ville
Mai
n W
ell
165
0B
lack
Cre
ek14
0X
WIL
-189
18U
-e3
pre-
1983
New
Wel
l2
695
Bla
ck C
reek
300
XX
WIL
-201
18U
-d1
9/19
93
Hem
ingw
ayH
igh
tank
189
1M
idde
ndor
f67
0X
XW
IL-3
712
S-c
18/
1970
Tupp
erw
are
291
4M
idde
ndor
f74
0X
XX
WIL
-176
12S
-h1
5/19
86In
dust
rial P
ark
388
6M
idde
ndor
f75
0X
XX
WIL
-213
12R
-s1
4/20
03
Kin
gstr
eeH
wy
377
167
0B
lack
Cre
ek45
0X
XX
WIL
-75
16T-
e23/
1978
Bro
ckin
gton
St.
295
3M
idde
ndor
f60
0X
XX
WIL
-118
17S
-u1
8/19
76S
tadi
um3
716
Bla
ck C
reek
, Mid
.25
0X
XW
IL-3
417
S-t1
8/19
69C
ount
y C
amp
61,
072
Mid
dend
orf
1,05
0X
XX
WIL
-203
16S
-n6
11/1
994
Lane
Rd
S45
-90
Wel
l2
694
Bla
ck C
reek
260
XX
XW
IL-1
7717
U-q
15/
1990
Stuc
key
Mai
n w
ell
128
6B
lack
Cre
ek15
0X
WIL
-32
13S
-il6/
1964
New
wel
lN
ew w
e2
610
Bla
cB
lack
Cre
ekC
ree
280
X28
0X
WIL
193
13S
j22/
1991
--
Sout
h W
illia
msb
urg
11,
129
Mid
dend
orf
950
XX
WIL
-207
18U
-b1
11/2
001
Cou
nty
Wat
er S
yste
m2
1,05
2B
lack
Cre
ek, M
id.
950
XX
WIL
-208
17T-
w1
2/20
02
Nes
mith
, Ind
iant
own,
11,
005
Bla
ck C
reek
, Mid
.70
0X
XX
WIL
-211
13S
-x1
8/20
02M
oore
svill
e W
ater
Sys
tem
21,
025
Mid
dend
orf
600
XX
XW
IL-2
1213
T-a5
9/20
02
X m
eans
"In
DN
R fi
les"
Tabl
e 1.
Wel
ls u
sed
by th
e m
ajor
pub
lic w
ater
-sup
ply
syst
ems
serv
ing
Will
iam
sbur
g C
ount
y, S
.C.
5
This pumpage is distributed as follows:
Greeleyville 0.101
Hemingway 0.413
Kingstree 1.021
Lane 0.768
Stuckey 0.029
South Williamsburg County Water System 0.281
Nesmith, Indiantown, Morrisville Water System 0.108
Sandridge Water System purchases water from Kings-tree. The foregoing pumpage figures were furnished by DHEC (South Carolina Department of Health and Environ-mental Control). Two of the five wells supplying the town of Andrews (in Georgetown County) are located in Williams-burg County.
PREVIOUS STUDIES
The most comprehensive study of Williamsburg Coun-ty’s ground water was by Philip Johnson of the U.S. Geo-logical Survey in 1978. His report described the resource in Clarendon and Williamsburg Counties (Johnson, 1978). In later years, Coastal Plain reports by the present writer touched on Williamsburg County (Newcome, 1989, 1993), as did potentiometric-contour maps by Stringfield (1989), Hockensmith and Waters (1998), and Hockensmith (2003, 2008).
The five counties that border Williamsburg County have had their ground-water resources described in specific coun-ty or multicounty reports. They are Florence County (Park, 1980); (Rodriguez and others, 1994); Marion County (Ro-driguez and others, 1994); Georgetown County (Pelletier, 1985); Berkeley County (Park, 1985); Clarendon County (Newcome, 2006).
AQUIFERS AND WELLS
Five geologic formations are available to supply wells in Williamsburg County. They are, from shallowest to deep-est, the Santee Limestone of Eocene age, the Black Mingo Formation of Paleocene age, and the Peedee, Black Creek, and Middendorf Formations of Cretaceous age. Shallow sand beds of Pleistocene age also are available for small supplies such as those for residential use and lawn irrigation. Water in all of the above, except the last mentioned, occurs under artesian conditions – that is, it is under pressure and rises in wells that penetrate the aquifer.
The highest yielding wells in and near Williamsburg County are those in the deepest of the above-listed forma-tions, the Middendorf. Pumping tests indicate aquifer trans-missivity (T) values averaging near 30,000 gpd/ft (gallons per day per foot of aquifer width) and ranging from 3,200
to 62,000. For those who prefer to express T in cubic feet per day per foot of aquifer width the foregoing T should be divided by 7.48. The average value of T for the Black Creek Formation pumping tests is near 12,000 gpd/ft, and the range is 1,700 to 80,000. No tests are available for the shallower Peedee Formation, Black Mingo Formation, and Santee Limestone in Williamsburg County.
DHEC records indicate that 143 wells were drilled in Williamsburg County in the year 2007. The following is a summary of their depth distribution:
Depth (ft) Number of Wells
<50 350-100 73 101-200 26201-500 40>500 1
This table, with half of the wells between 50 and 100 ft in depth, suggests that the Black Mingo Formation is an im-portant source of water for domestic supplies. Public-supply and industrial wells, on the other hand, produce water from the Black Creek and Middendorf Formations. In Williams-burg County, 16 municipal and rural water-system wells range in depth from 286 to 1,129 feet (Table 1). Black Creek Formation aquifers are screened in 7 of these wells and Mid-dendorf aquifers in 9 wells. The Black Creek wells average 260 gpm in yield, and the Middendorf wells average 780 gpm.
Farm-irrigation wells yield 50 to 500 gpm in the county and are producing from the Black Creek Formation . Larger yields probably could be obtained from deeper wells in the Middendorf Formation. The largest Williamsburg County yield in DNR records, 1,900 gpm, is from an industrial well in the Middendorf 5 miles north of Kingstree.
DNR records show that at least 121 wells in Wil-liamsburg County are capable of producing 120 gpm or more. There probably are others not in DNR records. Figure 3 shows the locations of wells capable of producing 200 gpm or more.
LOCATING THE AQUIFERS
The maps of Figure 4 portray the stratigraphic structure of the principal water-bearing formations of Wil-liamsburg County. The shallowest formation that occurs throughout the county and supplies at least half of the wells drilled for domestic supplies is the Black Mingo Forma-tion (A in Fig. 4). Between the base of the Black Mingo and the top of the Black Creek Formation (B in Fig. 4) lies the Peedee Formation that is mostly clay but contains significant sand aquifers in places. The Black Creek directly overlies the Middendorf Formation (C in Fig. 4). These two forma-tions, with an aggregate thickness ranging from 1,000 ft at the northern extremity of the county to 1,500 ft at the south-ern extremity, are difficult to differentiate on drilling logs and geophysical logs.
6
SE
EIN
SE
T
Kingstree
18
37
34
20,118
2173
271254
213
299227
260176
209 193
229235
211210 240
282212 241226
319230
239304
257
262303
175 301208189
201 207266280
238 305177
283311
256250
192
Figure 3. Wells in Williamsburg County capable of producing 200 gallons or more.
!(
!(
!(!(
!(
!(
!(
!(
!(!(
!(!(
12
26
3
3866
3929
203 4
11
75
174
S
T
16
!(
!(
Well with county number in DNR filesWell that has produced 1,000 gpm or more.Well WIL-66 produced 1,900 gpm.
For construction and production details of the wells shown here, go tohttp://www.dnr.sc.gov/water/hydro/WellRecords/Wells_main.htm
miles0 8 16 244
abcde
f g h i j
k l m n o
k q r s t
u v w x y
A well here wouldhave the grid number17R-w1 (or w2, w3, etc.,depending on the orderin which its record wasobtained).
17
R
20 19 18 17 16 15 14 13 12 11 10
Q
R
S
T
U
V
W
X
7
Figure 5. Contours depicting the deepest extent (in feet below sea level) of freshwater in Williamsburg County.
KingstreeGreeleyville
Hemingway
-1000
-1500
Figure 4. Structure-contour maps relating to the major aquifers in Williamsburg County.
Kingstree
Greeleyville
Hemingway-250
0
-500
B. Top of Black Creek Formation
Kingstree
Greeleyville
Hemingway
-750
-500
-1000
C. Top of Middendorf Formation
Kingstree
Greeleyville
Hemingway
-1000
-1500
-2000
D. Top of bedrock/Bottom of Cretaceous sediments
KingstreeGreeleyville
Hemingway 0
-100
-200
A. Base of Black Mingo Formation/Top of Cretaceous sediments
Contours, in feet below sea level, are fromColquhoun and others (1983).
Contours on top of bedrock have beenadjusted slightly by the present writer.
miles0 10 20
miles0 10 20
8
The few wells in the region (none in this county) that penetrate all of the formations and reach the top of bedrock indicate that freshwater is available from all of the aquifers above bedrock in the western half of Williamsburg County but not in the eastern half. At the county’s southern extrem-ity the 1,000-ft-thick Middendorf may have no freshwater aquifers in the bottom 750 ft. More information is needed to better define the lower limit of freshwater occurrence. Meanwhile, the map of Figure 5 (from Newcome, 1989, Fig. 7) is offered as a reasonable approximation. Compare it with the maps of Figure 4.
Moving from the geographical delineation of aquifer systems (Fig. 4) to specific location of aquifers leads us to geophysical logging of wells – most especially to electrical logging – by which the differences among sand, clay, and rock on a graph of the electrical resistance reveal the depth and thickness of the aquifers at the site examined. In addi-tion, the magnitude of the resistance provides information on the water quality. The map of Figure 6 shows the loca-tions of 24 electrical logs of wells in Williamsburg County and nearby in adjacent counties. These logs, selected on the bases of depth and clarity, provide sand intervals (as inter-preted by this writer) that are listed in Table 2.
TESTING THE WELLS AND AQUIFERS
The rate at which a well can be pumped is dependent upon three factors: (1) transmissivity of the aquifer; (2) well construction; (3) well efficiency. Transmissivity, which is the number of gallons per day that will pass through each foot of the aquifer’s width under unit hydraulic gradient, is determined by the aquifer’s hydraulic conductivity (K) and thickness (m); T=Km. Obviously, the greater the transmis-sivity the greater is the potential yield of wells. Next to be considered is the construction of the well. The greater the proportion of the aquifer thickness that is screened with properly selected well screen (optimum size of openings), the greater is the rate at which water can pass into the well. Finally, if the foregoing requirements are met the well re-mains only to be adequately developed to achieve good ef-ficiency. An efficient well is one that has a specific capac-ity (yield in gallons per minute for each foot of water-level drawdown while pumping) commensurate with the aquifer transmissivity. More on this later.
Well development usually entails “surge” pumping at various rates and for various periods (hours or days) to move the finer aquifer material near the well through the well screen and out of the well. An envelope of gravel commonly is installed around the well screen to help in this “filtering” process. The result is an increase in the effective well diam-eter and a minimum amount of sand or silt continuing to pass through the well screen and into the water supply.
Pumping tests provide the data needed to calculate transmissivity, specific capacity, and well efficiency. Pump-ing a well for several hours (preferably 24) at a constant rate and measuring the water level frequently while pumping and during a recovery period (hopefully equal in length to the
pumping period) constitutes a pumping test.Table 3 contains the results of 35 pumping tests (Loca-
tions on Fig. 7) in Williamsburg County and nearby in adja-cent counties (Berkeley, Clarendon, Florence, Georgetown, and Marion). The tests are all on wells screened in the Black Creek or Middendorf Formations. Two of the wells, FLO-247 and 259, are screened in both formations (Table 3). Very few of these tests were available to Johnson at the time of his report in 1978. The median T for the 21 Black Creek Forma-tion tests is 12,000 gpd/ft; for the 12 Middendorf tests it is nearly 30,000 gpd/ft. Specific capacities of the wells ranged from less than 1 to 24 gpm per foot of drawdown, and well efficiencies from 25 to 100 percent. The importance of well efficiency cannot be overemphasized. For example, a well that is only 50-percent efficient will have twice the water-level drawdown of a well that is fully efficient (100 percent). This results in a significant increase in pumping cost. Cal-culation of well efficiency involves several variables, but a reasonable approximation can be obtained by dividing the T by 2,000 to obtain the ideal specific capacity and then divid-ing that into the actual specific capacity, which is the gallons per minute yielded for each foot of water-level drawdown during pumping at a constant rate (Newcome 1997).
A few of the pumping tests of Table 3 revealed the near-by presence of hydrologic boundaries, which are sources of recharge or discharge. Recharge boundaries may be thicken-ing or increased permeability of the aquifer, drainage from another aquifer, or a surface source of water. Discharge boundaries may be thinning or pinching out of the aquifer, loss of water through a confining bed, or decreased permea-bility. Discharging effects on three tests possibly are caused by thinning of the aquifer in some direction or some other interruption in flow. The four tests for which a recharging boundary is indicated may be near a thickening of the aqui-fer or may be receiving leakage from a shallower or deeper aquifer.
All the tests are considered to represent artesian aqui-fers, although in only one test (GEO-214, near Andrews) was an observation well available to permit calculation of the storage coefficient (S).
EFFECTS OF PUMPING
The drawdown effects of pumping – for various periods of time and at various distances – can be calculated, using the hydraulics values produced by pumping tests. These effects can be shown as graphs (Fig. 8) that, in general, cover the transmissivity values determined for Williamsburg County aquifers (Table 3). For example, if a well completed in an artesian aquifer having a transmissivity of 10,000 gpd/ft is pumped for 10 consecutive days at 200 gpm it will cause about 12 ft of drawdown in that aquifer at a distance of 1,000 ft from the pumped well (Fig. 8A). This type of information is essential in the spacing of wells to avoid undue pumping interference.
9
MRN-78
CLA-66
BRK-29
FLO-274
3738
29
75
331473
200
199213
176124 193
203211118
212174
208201
177
196
Figure 6. Selected wells for which electric logs are available in and near Williamsburg County.
Kingstree
See Table 2 for sand intervalson these electric logs.
miles6 28 0 8 16 244
N
20 19 18 17 16 15 14 13 12 11 10
Q
R
S
T
U
V
W
X
10
belo
wla
nd21
023
216
820
942
045
021
525
046
580
6037
240
2
Cou
nty
wel
l num
ber
WIL
-14
WIL
-29
WIL
-33
WIL
-37
WIL
-38
WIL
-73
WIL
-75
WIL
-124
WIL
-174
WIL
-176
WIL
-177
WIL
-193
WIL
-196
S.C
. grid
num
ber
18V
-a1
16S
-g3
17U
-r1
12S
-c1
16S
-d1
13V
-g1
16T-
e213
S-f1
16T-
f112
S-h
117
U-q
113
S-j2
16U
-v1
Elev
atio
n, in
feet
MSL
6060
6555
6020
6540
6040
7853
58Lo
g de
pth
(ft)
660
1,31
879
089
01,
092
848
1,26
241
572
091
869
270
324
8Sa
nd in
terv
als,
in fe
et
176-
234
200-
220
130-
144
40-6
021
0-22
511
0-16
030
3-36
014
2-18
0-9
750
-75
62-8
820
5-29
018
6-22
3be
low
land
sur
face
556-
652
446-
500
152-
222
130-
164
433-
495
500-
530
538-
558
208-
282
104-
113
440-
460
138-
175
445-
462
238-
246
706-
814
348-
378
319-
377
659-
690
552-
590
598-
660
388-
412
222-
233
836-
866
348-
378
490-
510
883-
896
430-
480
454-
474
700-
730
675-
690
666-
678
413-
422
875-
920
510-
565
572-
610
1,03
0-1,
050
564-
678
521-
540
930-
962
740-
770
730-
769
465-
472
595-
645
1,06
5-1,
182
740-
790
610-
620
976-
1,00
088
6-1,
216
492-
526
668-
692
1,21
2-1,
318
650-
704
1,03
8-1,
048
535-
543
800-
884
614-
640
Cou
nty
wel
l num
ber
WIL
-199
WIL
-200
WIL
-201
WIL
-203
WIL
-208
WIL
-211
WIL
-212
WIL
-213
BR
K-2
9C
LA-6
6FL
O-2
74M
RN
-78
S.C
. grid
num
ber
16R
-n1
16R
-b1
18U
-d1
16S
-n6
17T-
w1
13S
-x1
13T-
a512
R-s
118
W-a
419
S-s
116
Q-s
110
Q-p
2El
evat
ion,
in fe
et M
SL73
7376
7575
5035
5260
9075
30Lo
g de
pth
(ft)
326
550
670
1,09
71,
222
1,21
51,
068
981
1,25
050
01,
050
1,22
5Sa
nd in
terv
als,
in fe
et
252-
268
158-
169
146-
158
230-
248
100-
167
166-
195
153-
185
120-
128
65-1
1022
-55
15-5
031
5-35
6be
low
land
sur
face
s
urfa
ce29
0-32
629
032
621
0-23
216
8-20
927
4-30
027
425
830
0-2
7825
827
842
0-45
021
5-25
046
5-49
212
8-1
492
128
4280
-91
60-8
637
2-40
214
291
8629
2-32
631
2-33
837
7-42
529
2-31
246
3-47
828
8-30
060
3-61
845
0-48
594
-101
100-
116
433-
454
331-
360
355-
370
477-
513
335-
360
535-
570
433-
472
792-
876
628-
640
103-
108
158-
170
505-
528
379-
495
620-
638
520-
533
555-
584
732-
805
483-
523
687-
745
111-
120
185-
203
720-
777
504-
540
753-
766
590-
610
912-
952
583-
615
760-
787
185-
202
236-
258
1,08
0-1,
097
675-
700
975-
995
838-
863
842-
860
248-
260
280-
325
707-
789
873-
925
1,06
0-1,
100
285-
305
372-
384
837-
858
1,00
4-1,
014
1,12
4-1,
240
310-
321
389-
403
885-
899
460-
476
408-
416
1,01
5-1,
055
446-
494
508-
578
672-
688
886-
901
1,02
4-1,
040
Tabl
e 2.
Fre
shw
ater
-san
d in
terv
als
indi
cate
d by
ele
ctric
logs
of w
ells
in a
nd n
ear W
illia
msb
urg
Cou
nty
(see
Fig
. 6 fo
r loc
atio
ns)
11
34 48 +14 3 63 29 29 16 34 42 16 71 57 18 125 50 67 66 55
X86
WIL
213
12R
s1X
886
M/7
086
710
35,0
0040
45 59 18 +5 26 23 25 56 33 36 66 42 17 25
7.2
Cou
nty
wel
l no.
S.C
. g norid .
Loca
tion
Ele lo
c. gD
epth
(ft)
Form
atio
naq
uife
r thi
c(ft
)
/ k.
Dat
e of
test
Dur
atio
(dd/
recn
(hr)
ov
)St
atic
WL
(ft)
Q(g
pm)
T(g
pd/ft
)S
Hyd
rol.
boun
d.W
ell e
ffic.
(p
erce
nt)
Sp. c
ap.
(gpm
/ft)
WIL
-11
16S
-y1
Kin
gstre
e (B
rook
s S
treet
)53
0B
C/
5/23
/197
75/
215
35,
500
100
3.5
WIL
-12
16S
-y2
Kin
gstre
e (2
nd A
ve.)
525
BC
/65
5/27
1977
5/2
108
8,20
010
0 4
.7W
IL-2
616
S-g
2K
ings
tree,
5 m
i NN
E75
5M
/1/
4/19
6124
/70
021
,000
100
10W
IL-3
317
U-r
1La
ne (S
eabo
ard
Roa
d)X
641
BC
/50
6/2/
1969
24/
150
3,40
070
1.1
WIL
-73
13V
-g1
And
rew
s, N
W e
dge
X76
8B
C/9
05/
12/1
975
48/
375
6,00
010
0 3
.9
WIL
-75
16T-
e2K
ings
tree,
SE
par
tX
670
BC
/120
5/1/
1978
72/9
575
422
,000
100
D10
WIL
-118
17S
-u1
Kin
gstre
e, N
W p
art
X95
3M
/40
11/1
5/19
7624
/150
03,
200
100
R 3
.5W
IL-1
2413
S-f1
Stu
ckey
, 3 1
/2 m
i wX
260
BC
/58
7/13
/198
124
/1.5
150
2,30
080
0.9
WIL
-174
16T-
f1K
ings
tree,
1 1
/2 m
i SX
640
BC
/85
4/18
/199
424
/240
26,
400
80 2
.5W
IL-1
7612
S-h
1H
emin
gway
, 1 1
/2 m
i SW
X91
4M
/50
5/14
/198
624
/475
338
,000
7013
WIL
-177
17U
-q1
Lane
, W s
ide
X69
4B
C/1
155/
1990
12/2
025
03,
700
70 1
.3W
IL-1
9213
V-o
2A
ndre
ws,
NW
cor
ner
X79
2B
C/9
51/
7/19
7548
/235
45,
000
90R
2.3
WIL
-193
13S
-j2S
tuck
eyX
610
BC
/105
2/27
/199
124
/125
037
,000
30D
5.8
WIL
-201
18U
-d1
Gre
eley
ville
X69
5B
C/1
506/
7/19
9424
/130
18,
400
100
4.1
WIL
-203
16S
-n6
Kin
gstre
e, 3
mi N
NE
X1,
072
M/9
011
/14/
1994
24/4
1,00
06,
000
100
3.9
WIL
-207
18U
-b1
Gre
eley
ville
, 3 m
i E1,
129
M/
12/1
0/20
0124
/14
952
30,0
0055
8.2
WIL
-208
17T-
w1
Sal
ters
, 2 1
/4 m
i SW
X1,
052
M/1
353/
17/2
002
24/1
595
242
,000
8017
WIL
-211
13S
-x1
Stu
ckey
, 5 m
i SW
X1,
005
M/1
008/
14/2
002
24/1
270
062
,000
7021
WIL
-212
13T-
a5N
esm
ithX
1,02
5M
/80
9/11
/200
224
/24
600
53,0
0025
6.6
WIL
-213
12R
-s1
Hem
ingw
ayH
emin
gway
886
M/7
04/
1/20
034/
1/20
0324
/24
/71
035
,000
407.
2
WIL
-221
16S
-f1K
ings
tree,
4 m
i N48
0B
C/7
52/
21/2
002
5/27
4,20
085
1.8
WIL
-223
15R
-s1
Cad
es, 5
1/2
mi E
340
BC
/40
2/6/
2002
5/19
1,70
095
0.8
BR
K-2
615
X-1
5Ja
mes
tow
nX
885
BC
/60
6/28
/198
130
/15
160
6,00
070
2.1
BR
K-2
4518
W-b
1S
t. S
teph
enX
1,26
0M
/7/
21/1
980
24/
305
23,0
0010
013
CLA
-61
18R
-b1
Turb
evill
e, 6
mi S
EX
393
BC
/50
8/19
8619
/60
827
,000
35R
? 4
.8C
LA-6
619
S-s
1M
anni
ng, 1
0 m
i EX
500
BC
/6/
23/1
997
24/4
807,
700
55 2
.1C
LA-7
419
S-j1
Fore
ston
, 7 m
i NN
E42
0B
C/6
012
/31/
2002
6/24
4,00
010
0 2
.5FL
O-1
5512
R-b
2Jo
hnso
nvill
e, 1
mi N
X88
0M
/50
10/8
/197
62/
620
18,0
0010
010
FLO
-247
15Q
-p3
Lake
City
(Hw
y 34
1E)
X61
8B
C,M
/120
8/3/
1983
24/7
.575
126
,000
100
15FL
O-2
5016
Q-t3
Lake
City
X
584
BC
,M/
8/12
/198
224
/14
751
47,0
0045
10FL
O-2
9616
Q-s
3La
ke C
ity (R
ae S
t.)59
0B
C/2
255/
18/1
993
24/2
1100
±80
,000
6024
GE
O-2
1412
W-r
2A
ndre
ws,
8 m
i SE
X82
5B
C/1
102/
28/1
983
24/6
8821
03,
000
0.00
001
65R
?1
GE
O-2
2011
S-s
2O
atla
nd, 3
mi S
EX
430
BC
/50
8/16
/198
324
/11
26,
000
45D
1.3
MR
N-7
810
Q-p
2B
ritto
ns N
eck,
3 m
i SX
537
BC
/22
4/30
/198
2
/6
032
7,00
030
±<1
MR
N-7
810
Q-p
2B
ritto
ns N
eck,
3 m
i SX
768
M/3
84/
24/1
982
/0.5
3512
,000
25±
<1.5
Expl
anat
ion
of ta
ble-
head
ing
abbr
evia
tions
:El
ec. l
og -
Ele
ctric
log.
X in
dica
tes
that
one
is o
n fil
e.Fo
rmat
ion/
aqui
fer t
hick
. (ft)
- B
M is
Bla
ck M
ingo
Fm
, BC
is B
lack
Cre
ek F
m, M
is M
idde
ndor
f Fm
. Thi
ckne
ss is
giv
en w
hen
it is
app
aren
t on
elec
tric
log.
Dur
atio
n (d
d/re
cov)
- H
ours
of d
raw
dow
n an
d re
cove
ry.
Stat
ic W
L (ft
) - N
onpu
mpi
ng w
ater
leve
l.Q
(gpm
) - P
umpi
ng ra
te, i
n ga
llons
per
min
ute,
for t
est.
T (g
pd/ft
) - T
rans
mis
sivi
ty, i
n ga
llons
per
day
per
foot
of a
quife
r wid
th. D
ivid
e by
7.4
8 to
obt
ain
units
of c
ubic
feet
per
day
per
foot
.S
- Sto
rage
coe
ffici
ent,
dim
ensi
onle
ss.
Sp. c
ap. (
gpm
/ft) -
Spe
cific
cap
acity
in g
allo
ns p
er m
inut
e pr
oduc
ed fo
r eac
h fo
ot o
f wat
er-le
vel d
raw
dow
n.W
ell e
ffic.
(per
cent
) - W
ell e
ffici
ency
, the
spe
cific
cap
acity
ach
ieve
d co
mpa
red
with
wha
t it s
houl
d be
for t
he in
dica
ted
trans
mis
sivi
ty.
Hyd
rol.
boun
d. -
Hyd
rolo
gic
boun
dary
; R, a
sou
rce
of re
char
ge; D
, dis
char
ge (a
bar
rier t
o flo
w)
Tabl
e 3.
Res
ults
of p
umpi
ng te
sts
of w
ells
in a
nd n
ear W
illia
msb
urg
Cou
nty
12
MRN-78
CLA-61
CLA-74
CLA-66
BRK-26
FLO-247FLO-296
FLO-250
FLO-155
GEO-220
BRK-245
GEO-214
26
121175
33
73
213223
176124
193221203
211118
212174
208201 207
177
192
BRK-631
Figure 7. Wells for which pumping-test results are given in Table 3.
N
Lane
Kingstree
Greeleyville
Andrews
Stuckey
Hemingway
20 19 18 17 16 15 14 13 12 11 10
Q
R
S
T
U
V
W
X
miles6 28 0 8 16 244
13
ASSUMED CONDITIONSPumping rate: 200 gpm. Transmissivity as indicated. Storage coefficient: 0.0002 (artesian)For other pumping rates, the drawdown will vary in direct proportion. For example, doubling the pumping rate will double the drawdown at a given distance and time.Transmissivity is given here in gallons per day per foot of aquifer width. To convert to cubic feet per day per foot (ft2/d), divide by 7.48.
0
10
20
30
1,000'500'200'
T = 10,000 gpd/ft
0
10
20
30
40
50
60
T = 5,000 gpd/ft
1,000'
500'
200'
100
120
140
0
20
40
60
80
T = 2,000 gpd/ft
1,000'
500'
200'
DR
AWD
OW
N (F
EET)
0.1 1 10 100 1,000
TIME (DAYS)
Figure 8A. Predicted pumping effects, at various times and distances, for aquifers in Williamsburg County.
14
ASSUMED CONDITIONSPumping rate: 200 gpm. Transmissivity as indicated. Storage coefficient: 0.0002 (artesian)For other pumping rates, the drawdown will vary in direct proportion. For example, doubling the pumping rate will double the drawdown at a given distance and time.Transmissivity is given here in gallons per day per foot of aquifer width. To convert to cubic feet per day per foot (ft2/d), divide by 7.48.
0
10
20
30
1,000'500'200'
T = 10,000 gpd/ft
0
10
20
30
40
50
60
T = 5,000 gpd/ft
1,000'
500'
200'
100
120
140
0
20
40
60
80
T = 2,000 gpd/ft
1,000'
500'
200'
DR
AWD
OW
N (F
EE
T)0.1 1 10 100 1,000
TIME (DAYS)
Figure 8B. Predicted pumping effects, at various times and distances, for aquifers in Williamsburg County.
15
QUALITY OF THE WATER
The chemical quality of ground water in Williamsburg County is generally good. Chemical analyses of water from 30 wells are listed in Table 4. Locations of those wells are shown on Figure 9. The formations represented by the anal-yses are Black Mingo (2 analyses), Peedee (1), Black Creek (17), and Middendorf (10). Except for the two Black Mingo samples and one from the Black Creek Formation, the water is very soft; the median hardness for Black Creek and Mid-dendorf samples being 6 mg/L (milligrams per liter) and 5 mg/L, respectively. Median dissolved-solids values for all samples are less than 300 mg/L. There have been reports of “cloudy” water from some wells. This has been identified as a colloidal suspension of aragonite, as reported by John-son (1978, p. 40). Only three of the samples in Table 4 had iron concentrations greater than the 0.3-mg/L recommended maximum.
WATER LEVELS
Potentiometric-contour maps of the Black Creek and Middendorf Formations in the South Carolina Coastal Plain were produced by Hockensmith (2003 and 2008) and reflect water levels in November 2001 and November 2004, re-spectively. Figure 10 of this report shows the Williamsburg County portion of Hockensmith’s latest maps and permits a comparison of the two chief aquifer-bearing formations in this county. It can be quickly seen that in the western part of the county there is little difference in the Black Creek and Middendorf water levels. In the east, cones of water-level depression exist in the Black Creek Formation at Andrews and in the Middendorf Formation at Hemingway. The cone at Andrews is much the more developed, but it has recovered about 15 ft in the 3-year period 2001-04. The cone in the Middendorf at Hemingway is much less developed and was little changed from 2001 to 2004.
SUMMARY AND CONCLUSIONS
Williamsburg County is underlain by sand-and-clay for-mations of Cretaceous age that are the principal sources of water for the wells that supply the communities, industries, and agriculture of the county. Many rural residential supplies are obtained from shallower aquifers of Paleocene, Eocene, and Pleistocene ages. The unconsolidated formations extend to depths of 1,000 to 2,000 ft below sea level in Williams-burg County (Fig. 4) and are underlain by Paleozoic bedrock –similar to that at the surface in the Piedmont of South Caro-lina. Potable water can be obtained as deep as 800 to 1,500 ft below sea level (Fig. 5).
Substantial aquifers are available throughout Williams-burg County. They are variable in thickness and extent and are best identified from geophysical logs and drilling sam-ples. Table 2 contains numerous examples of freshwater-sand intervals indicated on electrical logs.
Many large-yield wells have been constructed in the
county. Figure 3 shows the locations of all wells for which DNR has records of 200-gpm or greater yields. The largest reported yield is 1,900 gpm. Most of the large wells that are drilled are for crop irrigation and have yields of 200 to 400 gpm.
Controlled-pumping tests have indicated widely vary-ing aquifer-transmissivity values, which are dictated by a combination of aquifer thickness and hydraulic conductivity (permeability). The transmissivity, in turn, limits the specific capacity of a well (gpm per foot of water-level drawdown). Specific capacity is also limited by the well efficiency. A 50-percent-efficient well, for example, will require twice the drawdown of a 100-percent efficient well to produce the same yield. This increases the cost of pumping. Table 3 shows the variation in transmissivity, specific capacity, and well efficiency in wells for which pumping tests are avail-able. The hydraulic values determined by pumping tests can be used in predicting pumping effects for various times and distances, as illustrated in Figure 8.
The chemical quality of well water in Williamsburg County is generally good. Hardness and iron content are low. Dissolved-solids concentrations of 32 samples average 280 mg/L, well below the 500 mg/L recommended maxi-mum level but higher than the average levels in Clarendon County to the west and Florence County to the north. This may be at least partly due to the considerably greater av-erage depth of the sampled wells in Williamsburg County. Georgetown County, on the east, had higher dissolved solids than Williamsburg County for wells of comparable depth. Cloudiness of the water has been reported in some wells and has varied with time in its persistence. It was identified be-fore 1978 (year of Johnson’s report) as being “a colloidal suspension of aragonite (CaCO3).” See Johnson (1978, p. 40) for a more in-depth discussion.
Artesian water levels for the major aquifer systems have been affected by pumping over the years. Serious drawdown effects are exhibited on potentiometric maps in the vicinities of Andrews and Hemingway (see Fig. 10). The water lev-els may be restored by reducing pumpage, repositioning of wells, or resorting to artificial recharge from surface-water sources as in Horry County in the northeast.
16
Cou
nty
wel
l no
.S
.C. g
rid
no.
Loca
tion
Dat
eD
epth
(ft)
/form
atio
nS
ilica
Iron
Man
-ga
nese
Cal
cium
Mag
ne-
sium
Sod
ium
Pot
as-
sium
Bic
ar-
bona
teS
ulfa
teC
hlor
ide
Fluo
ride
Nitr
ate
Dis
solv
edso
lids
Har
d-ne
sspH
Ana
lyst
212
R-v
2H
emin
gway
3/19
5945
6/B
C14
0.25
0.01
8.4
3.6
1
62
12
39
323
31
1.0
0.5
470
368.
6U
516
S-n
8H
emin
gway
1/19
5555
0/B
C24
.13
-2.
1.2
79
2.6
173
7.5
3.0
2.2
.9
216
68.
5U
1116
S-y
1H
emin
gway
, Wel
l 51/
1955
530/
BC
34 .
12 .
001.
6.2
77
3.0
168
8.3
3.5
1.5
.0
021
05
8.8
U14
18V
-a1
Lane
4/19
6966
0/B
C13
.18
-1.
5.3
91
3.2
219
7.2
3.3
2.2
.2
231
58.
5U
1812
R-v
1H
emin
gway
6/19
8455
0/B
C13
.10
.00
.9.4
135
1.6
368
6.1
48
1.8
.0
139
14
8.6
WR
C25
16S
-g1
Kin
gstre
e8/
1960
670/
M21
.48
.00
3.4
.4 7
22.
816
09.
515
1.
8
.00
212
118.
4U
3116
V-f1
Lane
, 5 m
i SE
5/19
6997
2/M
15 .
18-
1
.1 7
51.
517
311
5.2
.8
.1
202
39.
1U
3213
S-i1
Stu
ckey
, Wel
l 16/
1984
286/
BC
18 .
01 .
003
1.
2
99
9.2
324
5.6
10
2.2
.0
032
813
8.5
WR
C33
17U
-r1
Lane
, Wel
l 16/
1984
641/
BC
16 .
00 .
04 .8
.3 8
73.
721
47.
92.
22.
0
.00
208
129.
1W
RC
3417
S-t1
Kin
gstre
e, W
ell 3
6/19
8471
6/B
C22
.00
.06
1.2
.2 6
73.
117
37.
03.
21.
4
.00
192
5 9
.0
WR
C37
12S
-c1
Hem
ingw
ay, W
ell 1
6/19
8489
1/B
C15
.00
.01
.6.5
135
1.6
370
5.6
29
1.8
-37
44
8.6
WR
C52
16T-
y1S
alte
rs, 2
mi E
5/19
6945
0/B
C17
.09
-30
4.5
3
25.
418
49.
46.
5 .
4 .
417
692
7.9
U54
11S
-h2
Out
land
2/19
6932
5/B
C26
.06
.01
1.5
.415
08.
338
07.
210
2.
3 .
140
05
8.3
U66
16S
-d2
Kin
gstre
e1/
1970
750/
M15
4.6
-
2.3
.3 6
02.
915
86.
83.
9 .
9 .
618
06
8.5
U73
13V
-g1
And
rew
s4/
1977
768/
BC
16 .
13 .
005.
3.4
160
5.1
400
9.4
14
1.7
-42
215
8.5
U75
16T-
e2K
ings
tree,
Wel
l 16/
1984
670/
BC
25 .
00 .
051.
2.4
90
5.4
227
5.2
4.8
1.4
.0
024
77
8.8
WR
C11
519
U-k
1G
reel
eyvi
lle, 3
mi S
SW
4/19
8011
9/B
M10
.02
.01
3.8
1.6
3.0
1.5
-13
5.5
.1
3-
121
101
8.0
W
RC
118
17S
-u1
Kin
gstre
e, W
ell 2
6/19
8495
3/M
25 .
00 .
061.
7 .5
7 7
53.
421
630
48
1.4
.0
029
38
8.0
W
RC
119
14W
-p1
And
rew
s,9
miS
W10
/198
190
/BM
-.5
.05
--
--
106
-5
--
130
847.
3D
HE
C11
914
W-p
1A
ndre
ws,
9m
iSW
10/1
981
90/B
M-
.5 .0
5-
--
106
-5
--
130
847.
3D
HE
C12
413
S-f1
Stu
ckey
, 4 m
i W7/
1981
260/
PD
- .
29 <
.01
8.
8 .9
211
38.
814
17.
54.
01.
8 .2
240
267.
9C
om17
416
T-f1
Kin
gstre
e, 2
mi S
SW
12/1
983
650/
BC
38<.
01 <
.01
.9
.23
99
6.2
242
11
3.
41.
3
.00
280
139.
1W
RC
176
12S
-h1
Hem
ingw
ay, W
ell
25/
1986
914/
M-
<.1
<
.1
1.
4 .3
821
61.
932
59.
233
1.
8<1
.0
435
5 8
.0
Com
177
17U
-q1
Lane
, Wel
l 210
/199
069
4/B
C-
<.0
5
.05
2.2
.3 6
03
12
610
<5
1.
9<.
1 14
07
8.2
Com
189
18U
-e3
Gre
eley
ville
6/19
8465
0/B
C15
.00
.0
5 .9
.25
72
3.8
176
7
1.7
1.3
.0
019
14
9.1
WR
C19
213
V-o
2A
ndre
ws,
Wel
l 51/
1975
792/
BC
16 .
01
.00
2
.00
146
146
298
1
12
1.6
-32
85
8.8
Com
203
16S
-n6
Kin
gstre
e, 3
mi N
, Wel
l 612
/199
41,
072/
M-
.05
.0
5 1.
9.3
70
20
18
8<5
26
1.4
<.1
190
67.
7C
om21
113
S-x
1W
illia
msb
urg
Co.
W&
SW
ell 1
Stu
cky,
4 m
i SW
212
13T-
a5W
illia
msb
urg
Co.
W&
SW
ell 2
Stu
cky,
5 m
i S20
718
U-b
1S
outh
Will
iam
sbur
g C
o. W
ater
Sys
tem
Gre
eley
ville
, 3 m
i E21
312
R-s
1H
emin
gway
, 1.5
mi N
4/20
0388
6/M
- .
16<.
011.
3-
189
1.7
323
7
36
1.5
<.5
403
3-
Com
<.02
352
8.5
Com
-7.
5C
om
8.5
Com
4
-26
912
30
1.8
.04
<.01
1.5
--
-31
1
<.5
440
<2.5
Form
atio
n: B
M, B
lack
Min
go; P
D, P
eede
e; B
C, B
lack
Cre
ek; M
, Mid
dend
orf
8/20
021,
005/
M
1,02
5/M
12/2
001
9/20
02
1,12
9/M
- - -
.05
-1.
6-
390
1.2
.27.
224
Ana
lyst
: U, U
.S. G
eolo
gica
l Sur
vey;
WR
C, S
outh
Car
olin
a W
ater
Res
ourc
es C
omm
issi
on; D
HE
C, S
outh
Car
olin
a D
epar
tmen
t of H
ealth
and
Env
ironm
enta
l Con
trol;
Com
, Com
mer
cial
.06
<.01
<1
.2
165
-49
42.
524
2.
4
149
Tabl
e 4.
Che
mic
al a
naly
sis
of w
ater
from
wel
ls in
Will
iam
sbur
g C
ount
y (c
onst
ituen
ts a
nd h
ardn
ess
are
in m
illig
ram
s pe
r lite
r)
17
2
5
1837
326625
54
341175
52
3314
31 73
213
176124
203211
118212
174
189
207115177
192
119
Figure 9. Wells for which chemical analyses are given in Table 4.
Kingstree
miles6 28 0 8 16 244
N
20 19 18 17 16 15 14 13 12 11 10
Q
R
S
T
U
V
W
X
18
River
0 -25
25
-50
50
-75
-100
-125
Kingstree
Andrews
Santee
A. Black Creek Formation
N
B. Middendorf Formation
Hemingway
River
Santee
25
0-25
50
25
Figure 10. 2004 Potentiometric maps of the major water-producing formationsof Williamsburg County (from Hockensmith, 2008 a, b).
Potentiometric contours are in feet relative to sea level.
miles10 0 10 20 30
19
REFERENCES
Colquhoun, D.J. Woollen, I.D., Van Nieuwenhuise, D.S., Padgett, G.G., Oldham, R.W., Boylan, D.C., Bishop, J.W., and Howell, P.D., 1983, Surface and subsurface stratigraphy, structure and aquifers of the South Carolina Coastal Plain: University of South Carolina, Department of Geology, 78 p.
Hockensmith, B.L., and Waters, K.E., 1998, Potentiometric surface of the Middendorf aquifer in South Carolina – November 1996: South Carolina Department of Natural Resources Water Resources Report 19, 1 sheet.
Hockensmith, B.L., 2008a, Potentiometric surface of the Middendorf aquifer in South Carolina – November 2004: South Carolina Department of Natural Resources Water Resources Report 46, 11 p. and 1 sheet.
------------ 2008b, Potentiometric surface of the Black Creek aquifer in South Carolina – November 2004: South Carolina Department of Natural Resources Water Resources Report 47, 10 p. and 1 sheet.
Johnson, P.W., 1978, Reconnaissance of the ground-water resources of Clarendon and Williamsburg Counties, South Carolina: South Carolina Water Resources Commission Report No. 13, 44 p.
Newcome, Roy, Jr., 1989, Ground-water resources of South Carolina’s Coastal Plain – 1988: South Carolina Water Resources Commission Report 167, 127 p.
------------ 1993, Pumping tests of the Coastal Plain aquifers in South Carolina – with a discussion of aquifer and well characteristics: South Carolina Water Resources Commission Report 174, 52 p.
------------ 1997 , Well efficiency – its importance and its calculation, in Contributions to the hydrology of South Carolina: South Carolina Department of Natural Resources Water Resources Report 14, p. 45-47.
------------ 2006, Ground-water resources of Clarendon County, South Carolina: South Carolina Department of Natural Resources Water Resources Report 40, 21 p.
Park, A.D., 1980, The ground-water resources of Sumter and Florence Counties, South Carolina: South Carolina Water Resources Commission Report 133, 43 p.
------------ 1985, The ground-water resources of Charleston, Berkeley, and Dorchester Counties, South Carolina: South Carolina Water Resources Commission Report 139, 146 p.
Pelletier, A.M., 1985, Ground-water conditions and water-supply alternatives in the Waccamaw Capacity Use Area, South Carolina: South Carolina Water Resources Commission Report 144, 32 p.
Rodriguez, J.A., Newcome, Roy, Jr., and Wachob, Andrew, 1994, Ground-water resources of Darlington, Dillon, Florence, Marion, and Marlboro Counties, South Carolina – with an analysis of management alternatives for the city of
Florence: South Carolina Department of Natural Resources Water Resources Division Report 1, 119 p.